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The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html Committee on Alternatives and Strategies for Future Hydrogen Production and Use Board on Energy and Environmental Systems Division on Engineering and Physical Sciences Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html NATIONAL ACADEMIES PRESS • 500 Fifth Street, N.W • Washington, DC 20001 NOTICE: The project that is the subject of this report was approved by the Governing Board of the National Research Council, whose members are drawn from the councils of the National Academy of Sciences, the National Academy of Engineering, and the Institute of Medicine The members of the committee responsible for the report were chosen for their special competences and with regard for appropriate balance This report and the study on which it is based were supported by Grant No DE-FG3602GO12114 from the U.S Department of Energy Any opinions, findings, conclusions, or recommendations expressed in this publication are those of the authors and not necessarily reflect the views of the organizations or agencies that provided support for the project International Standard Book Number 0-309-09163-2 (Book) International Standard Book Number 0-309-53068-7 (PDF) Library of Congress Control Number 2004108605 Available in limited supply from: Board on Energy and Environmental Systems National Research Council 500 Fifth Street, N.W KECK-W934 Washington, DC 20001 202-334-3344 Additional copies available for sale from: National Academies Press 2101 Constitution Avenue, N.W Box 285 Washington, DC 20055 800-624-6242 or 202-334-3313 (in the Washington metropolitan area) http://www.nap.edu Copyright 2004 by the National Academy of Sciences All rights reserved Printed in the United States of America Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html The National Academy of Sciences is a private, nonprofit, self-perpetuating society of distinguished scholars engaged in scientific and engineering research, dedicated to the furtherance of science and technology and to their use for the general welfare Upon the authority of the charter granted to it by the Congress in 1863, the Academy has a mandate that requires it to advise the federal government on scientific and technical matters Dr Bruce M Alberts is president of the National Academy of Sciences The National Academy of Engineering was established in 1964, under the charter of the National Academy of Sciences, as a parallel organization of outstanding engineers It is autonomous in its administration and in the selection of its members, sharing with the National Academy of Sciences the responsibility for advising the federal government The National Academy of Engineering also sponsors engineering programs aimed at meeting national needs, encourages education and research, and recognizes the superior achievements of engineers Dr Wm A Wulf is president of the National Academy of Engineering The Institute of Medicine was established in 1970 by the National Academy of Sciences to secure the services of eminent members of appropriate professions in the examination of policy matters pertaining to the health of the public The Institute acts under the responsibility given to the National Academy of Sciences by its congressional charter to be an adviser to the federal government and, upon its own initiative, to identify issues of medical care, research, and education Dr Harvey V Fineberg is president of the Institute of Medicine The National Research Council was organized by the National Academy of Sciences in 1916 to associate the broad community of science and technology with the Academy’s purposes of furthering knowledge and advising the federal government Functioning in accordance with general policies determined by the Academy, the Council has become the principal operating agency of both the National Academy of Sciences and the National Academy of Engineering in providing services to the government, the public, and the scientific and engineering communities The Council is administered jointly by both Academies and the Institute of Medicine Dr Bruce M Alberts and Dr Wm A Wulf are chair and vice chair, respectively, of the National Research Council www.national-academies.org Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html COMMITTEE ON ALTERNATIVES AND STRATEGIES FOR FUTURE HYDROGEN PRODUCTION AND USE MICHAEL P RAMAGE, NAE,1 Chair, ExxonMobil Research and Engineering Company (retired), Moorestown, New Jersey RAKESH AGRAWAL, NAE, Air Products and Chemicals, Inc., Allentown, Pennsylvania DAVID L BODDE, University of Missouri, Kansas City ROBERT EPPERLY, Consultant, Mountain View, California ANTONIA V HERZOG, Natural Resources Defense Council, Washington, D.C ROBERT L HIRSCH, Science Applications International Corporation, Alexandria, Virginia MUJID S KAZIMI, Massachusetts Institute of Technology, Cambridge ALEXANDER MACLACHLAN, NAE, E.I du Pont de Nemours & Company (retired), Wilmington, Delaware GENE NEMANICH, Independent Consultant, Sugar Land, Texas WILLIAM F POWERS, NAE, Ford Motor Company (retired), Ann Arbor, Michigan MAXINE L SAVITZ, NAE, Consultant (retired, Honeywell), Los Angeles, California WALTER W (CHIP) SCHROEDER, Proton Energy Systems, Inc., Wallingford, Connecticut ROBERT H SOCOLOW, Princeton University, Princeton, New Jersey DANIEL SPERLING, University of California, Davis ALFRED M SPORMANN, Stanford University, Stanford, California JAMES L SWEENEY, Stanford University, Stanford, California Project Staff Board on Energy and Environmental Systems (BEES) MARTIN OFFUTT, Study Director ALAN CRANE, Senior Program Officer JAMES J ZUCCHETTO, Director, BEES PANOLA GOLSON, Senior Project Assistant NAE Program Office JACK FRITZ, Senior Program Officer Consultants Dale Simbeck, SFA Pacific, Inc Elaine Chang, SFA Pacific, Inc 1NAE = member, National Academy of Engineering v Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html BOARD ON ENERGY AND ENVIRONMENTAL SYSTEMS DOUGLAS M CHAPIN, NAE,1 Chair, MPR Associates, Alexandria, Virginia ROBERT W FRI, Vice Chair, Resources for the Future, Washington, D.C ALLEN J BARD, NAS,2 University of Texas, Austin DAVID L BODDE, University of Missouri, Kansas City PHILIP R CLARK, NAE, GPU Nuclear Corporation (retired), Boonton, New Jersey CHARLES GOODMAN, Southern Company Services, Birmingham, Alabama DAVID G HAWKINS, Natural Resources Defense Council, Washington, D.C MARTHA A KREBS, California Nanosystems Institute (retired), Los Angeles, California GERALD L KULCINSKI, NAE, University of Wisconsin, Madison JAMES J MARKOWSKY, NAE, American Electric Power (retired), North Falmouth, Massachusetts DAVID K OWENS, Edison Electric Institute, Washington, D.C WILLIAM F POWERS, NAE, Ford Motor Company (retired), Ann Arbor, Michigan EDWARD S RUBIN, Carnegie Mellon University, Pittsburgh, Pennsylvania MAXINE L SAVITZ, NAE, Honeywell, Inc (retired), Los Angeles, California PHILIP R SHARP, Harvard University, Cambridge, Massachusetts ROBERT W SHAW, JR., Aretê Corporation, Center Harbor, New Hampshire SCOTT W TINKER, University of Texas, Austin JOHN J WISE, NAE, Mobil Research and Development Company (retired), Princeton, New Jersey Staff JAMES J ZUCCHETTO, Director ALAN CRANE, Senior Program Officer MARTIN OFFUTT, Program Officer DANA CAINES, Financial Associate PANOLA GOLSON, Project Assistant NAE = member, National Academy of Engineering NAS = member, National Academy of Sciences vi Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html Acknowledgments The Committee on Alternatives and Strategies for Future Hydrogen Production and Use wishes to acknowledge and thank the many individuals who contributed significantly of their time and effort to this National Academies’ National Research Council (NRC) study, which was done jointly with the National Academy of Engineering (NAE) Program Office The presentations at committee meetings provided valuable information and insight on advanced technologies and development initiatives that assisted the committee in formulating the recommendations included in this report The committee expresses its thanks to the following individuals who briefed the committee: Alex Bell (University of California, Berkeley); Larry Burns (General Motors); John Cassidy (UTC, Inc.); Steve Chalk (U.S Department of Energy [DOE]); Elaine Chang (SFA Pacific); Roxanne Danz (DOE); Pete Devlin (DOE); Jon Ebacher (GE Power Systems); Charles Forsberg (Oak Ridge National Laboratory [ORNL]); David Friedman (Union of Concerned Scientists); David Garman (DOE); David Gray (Mitretek); Cathy Gregoire-Padro (National Renewable Energy Laboratory [NREL]); Dave Henderson (DOE); Gardiner Hill (BP); Bill Innes (ExxonMobil Research and Engineering); Scott Jorgensen (General Motors); Nathan Lewis (California Institute of Technology); Margaret Mann (NREL); Lowell Miller (DOE); JoAnn Milliken (DOE); Joan Ogden (Princeton University); Lynn Orr, Jr (Stanford University); Ralph Overend (NREL); Mark Pastor (DOE); David Pimentel (Cornell University); Dan Reicher (Northern Power Systems and New Energy Capital); Neal Richter (ChevronTexaco); Jens Rostrup-Nielsen (Haldor Topsoe); Dale Simbeck (SFA Pacific); and Joseph Strakey (DOE National Energy Technology Laboratory) The committee offers special thanks to Steve Chalk, DOE Office of Hydrogen, Fuel Cells and Infrastructure Technologies, and to Roxanne Danz, DOE Office of Energy Efficiency and Renewable Energy, for being responsive to its needs for information In addition, the committee wishes to acknowledge Dale Simbeck and Elaine Chang, both of SFA Pacific, Inc., for providing support as consultants to the committee Finally, the chair gratefully recognizes the committee members and the staffs of the NRC’s Board on Energy and Environmental Systems and the NAE Program Office for their hard work in organizing and planning committee meetings and their individual efforts in gathering information and writing sections of the report This report has been reviewed in draft form by individuals chosen for their diverse perspectives and technical expertise, in accordance with procedures approved by the NRC’s Report Review Committee The purpose of this independent review is to provide candid and critical comments that will assist the institution in making its published report as sound as possible and to ensure that the report meets institutional standards for objectivity, evidence, and responsiveness to the study charge The review comments and draft manuscript remain confi- vii Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html viii ACKNOWLEDGMENTS dential to protect the integrity of the deliberative process We wish to thank the following individuals for their review of this report: Allen Bard (NAS), University of Texas, Austin; Seymour Baron (NAE), retired, Medical University of South Carolina; Douglas Chapin (NAE), MPR Associates, Inc.; James Corman, Energy Alternative Systems; Francis J DiSalvo (NAS), Cornell University; Mildred Dresselhaus (NAE, NAS), Massachusetts Institute of Technology; Seth Dunn, Yale School of Management, and School of Forestry & Environmental Studies; David Friedman, Union of Concerned Scientists; Robert Friedman, The Center for the Advancement of Genomics; Robert D Hall, CDG Management, Inc.; James G Hansel, Air Products and Chemicals, Inc.; H.M (Hub) Hubbard, retired, Pacific International Center for High Technology Research; Trevor Jones (NAE), Biomec; James R Katzer (NAE), ExxonMobil Research and Engineering Company; Alan Lloyd, California Air Resources Board; John P Longwell (NAE), retired, Massachusetts Institute of Technology; Alden Meyer, Union of Concerned Scientists; Robert W Shaw, Jr., Aretê Corporation; and Richard S Stein, (NAS, NAE) retired, University of Massachusetts Although the reviewers listed above have provided many constructive comments and suggestions, they were not asked to endorse the conclusions or recommendations, nor did they see the final draft of the report before its release The review of this report was overseen by William G Agnew (NAE), General Motors Corporation (retired) Appointed by the National Research Council, he was responsible for making certain that an independent examination of this report was carried out in accordance with institutional procedures and that all review comments were carefully considered Responsibility for the final content of this report rests entirely with the authoring committee and the institution Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html Contents EXECUTIVE SUMMARY 1 INTRODUCTION Origin of the Study, Department of Energy Offices Involved in Work on Hydrogen, Scope, Organization, and Focus of This Report, A FRAMEWORK FOR THINKING ABOUT THE HYDROGEN ECONOMY Overview of National Energy Supply and Use, 11 Energy Transitions, 11 Motivation and Policy Context: Public Benefits of a Hydrogen Energy System, 14 Scope of the Transition to a Hydrogen Energy System, 16 Competitive Challenges, 17 Energy Use in the Transportation Sector, 22 Four Pivotal Questions, 23 11 THE DEMAND SIDE: HYDROGEN END-USE TECHNOLOGIES Transportation, 25 Stationary Power: Utilities and Residential Uses, 30 Industrial Sector, 34 Summary of Research, Development, and Demonstration Challenges for Fuel Cells, 34 Findings and Recommendations, 35 25 TRANSPORTATION, DISTRIBUTION, AND STORAGE OF HYDROGEN Introduction, 37 Molecular Hydrogen as Fuel, 38 The Department of Energy’s Hydrogen Research, Development, and Demonstration Plan, 43 Findings and Recommendations, 43 37 SUPPLY CHAINS FOR HYDROGEN AND ESTIMATED COSTS OF HYDROGEN SUPPLY Hydrogen Production Pathways, 45 Consideration of Hydrogen Program Goals, 46 Cost Estimation Methods, 48 Unit Cost Estimates: Current and Possible Future Technologies, 49 ix Copyright © National Academy of Sciences All rights reserved 45 The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html x CONTENTS Comparisons of Current and Future Technology Costs, 54 Unit Atmospheric Carbon Releases: Current and Possible Future Technologies, 58 Well-to-Wheels Energy-Use Estimates, 60 Findings, 60 IMPLICATIONS OF A TRANSITION TO HYDROGEN IN VEHICLES FOR THE U.S ENERGY SYSTEM Hydrogen for Light-Duty Passenger Cars and Trucks: A Vision of the Penetration of Hydrogen Technologies, 65 Carbon Dioxide Emissions as Estimated in the Committee’s Vision, 69 Some Energy Security Impacts of the Committee’s Vision, 73 Other Domestic Resource Impacts Based on the Committee’s Vision, 75 Impacts of the Committee’s Vision for Total Fuel Costs for Light-Duty Vehicles, 79 Summary, 81 Findings, 83 64 CARBON CAPTURE AND STORAGE The Rationale of Carbon Capture and Storage from Hydrogen Production, 84 Findings and Recommendations, 90 84 HYDROGEN PRODUCTION TECHNOLOGIES Hydrogen from Natural Gas, 91 Hydrogen from Coal, 93 Hydrogen from Nuclear Energy, 94 Hydrogen from Electrolysis, 97 Hydrogen Produced from Wind Energy, 99 Hydrogen Production from Biomass and by Photobiological Processes, 101 Hydrogen from Solar Energy, 103 91 CROSSCUTTING ISSUES Program Management and Systems Analysis, 106 Hydrogen Safety, 108 Exploratory Research, 110 International Partnerships, 112 Study of Environmental Impacts, 113 Department of Energy Program, 114 106 10 MAJOR MESSAGES OF THIS REPORT Basic Conclusions, 116 Major Recommendations, 118 116 REFERENCES 123 APPENDIXES A Biographies of Committee Members B Letter Report C DOE Hydrogen Program Budget D Presentations and Committee Meetings E Spreadsheet Data from Hydrogen Supply Chain Cost Analyses F U.S Energy Systems G Hydrogen Production Technologies: Additional Discussion H Useful Conversions and Thermodynamic Properties 129 133 137 139 141 194 198 240 Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 213 APPENDIX G 800 He cycle S–CO2 cycle Energy required (HHV) for producing kg H2 (MJ/kg-H2) 700 600 500 400 279 300 269 265 252 200 Operation range of S-CO2 cycle Operation range of He cycle 100 350 400 450 500 550 600 650 700 750 800 850 900 950 o Turbine inlet temperature/electrolysis temperature ( C) FIGURE G-6 The energy needs for hydrogen production by the gas turbine modular helium reactor (He cycle) high-temperature electrolysis of steam (HTES) and the supercritical CO2 (S-CO2 cycle) advanced gas-cooled reactor HTES technologies NOTE: HHV = higher heating value sulfur cycles are depicted schematically in Figure G-7.) The most promising form consists of the following three chemical reactions, which yield the dissociation of water (Brown et al., 2003): I2 + SO2 + 2H2O → 2HI + H2SO4 H2SO4 → SO2 + H2O + 1/2O2 2HI → I2 + H2 (120°C) (830°C–900°C) (300°C–450°C) A hybrid sulfur-based process does not require iodine and has the same high-temperature step as sulfur iodine but a single electrochemical low-temperature step that forms sulfuric acid That electrolysis step makes sulfuric acid at very low voltage (power) The low-voltage electrolysis step (low power compared with electrolysis of water) may allow much larger scale-up of the electrochemical cells (Highvoltage systems have high internal heat generation rates that often limit the scale-up of a single cell.) The efficiency of this process is about the same as that of the SI process, but is influenced by the efficiency of the electrical power cycle It is one of only four processes for which a fully integrated process has been demonstrated in a hood It is the only process for which a full conceptual design report for a fullscale facility has been developed Lastly, like the SI process, it has the potential for major improvements The SI cycle requires high operating temperatures but offers the opportunity for high-efficiency conversion of heat to hydrogen energy, ηH, as shown in Figure G-8 The SI cycle can be coupled to the modular high-temperature reactor (MHR) (a version of the HTGR) (LaBar, 2002) This reactor consists of 600 megawatt-thermal (MWth) modules, which are cooled by helium gas, with high coolant exit temperatures that can provide the necessary heat to the SI reactions The coupling of the MHR and SI cycle, MHR-SI, provides a large-scale, centralized production of hydrogen The MHR-SI is a capital-intensive technology Future cost reduction can be achieved from high efficiency by devising materials that can withstand higher temperatures Reactor materials that are temperature-, irradiation- and corrosion-resistant would be needed Also, possible reduc- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 214 APPENDIX G High-Temperature Reactions Low-Temperature Hydrogen Reactions Water Oxygen H 2O O2 H2 SO2, H2O I2 Heat Heat I 2+ SO2 + 2H2O 2HI + H2SO4 H2 O + SO H2 O + SO2+1/2O2 H2SO4 o 850C H2SO4 2HI H 2+ I2 o 450C HI o 120C Base Case Sulfur Iodine Oxygen O2 SO2, HO4 Heat o 700C Membrane Separation H2SO4 H2O + SO3 H2O + SO2+1/2O Electrolysis (0.6 V [actual]) SO2 + 2H2O H2SO4+ H2 Inorganic Membrane H2SO4 H2 Hybrid Sulfur (Westinghouse, GA-22, and Ispra Mark II) Hydrogen Water Hydrogen H2O SO2, H2O H2 Br Br2 Reject Br2+ SO + 2H2O 2HBr + H2SO4 H2SO4 Heat Electrolysis (0.8 V [actual]) 77C 2HBr H2 + Br2 o HBr o 77C Reject Heat Ispra Mark 13 FIGURE G-7 Depiction of the most promising sulfur thermochemical cycles for water splitting Courtesy of Charles Forsberg, Oak Ridge National Laboratory tion in the capital cost may result from improved catalytic materials and higher hydrogen production capacity in each facility Calcium-Bromine-Iron Cycle The calcium-bromine-iron (Ca-Br, or UT-3) cycle involves solid-gas interactions that may facilitate the reagent-product separations, as opposed to the all-fluid interactions in the SI cycle, but it will introduce the problems of solids handling, support, and attrition This process is formed of the following reactions (Doctor et al., 2002): CaBr2 + H2O → CaO + 2HBr CaO + Br2 → CaBr2 + 1/2O2 (730°C) (550°C) Fe3O4 + 8HBr → 3FeBr2 + 4H2O + Br2 3FeBr2 + 4H2O → Fe3O4 + 6HBr + H2 (220°C) (650°C) The thermodynamics of these reactions have been found favorable However, the hydrogen production efficiency of the process is limited to about 40 percent, owing to the melting point of Ca-Br2 at 760°C (Schultz et al., 2002) Other Cycles Argonne National Laboratory’s Chemical Engineering Division is studying other cycles like the copper-chlorine thermochemical cycle The energy efficiency of the process is projected to be 40 to 45 percent (ANL, 2003) This work is currently being investigated only by ANL, at a bench-scale R&D level, and no pilot demonstra- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 215 APPENDIX G 0.7 2000 Energy Efficiency 1800 0.6 Thermal-to-hydrogen energy efficiency (ηH) Energy required to produce kg H2 (MJ/kg-H2) 1600 0.5 1400 1200 0.4 1000 0.3 800 600 0.2 400 0.1 200 650 700 750 800 850 900 950 1000 Temperature ( oC) FIGURE G-8 Estimated thermal-to-hydrogen efficiency (ηH) of the sulfur-iodine (SI) process and thermal energy required to produce a kilogram of hydrogen from the modular high-temperature reactor-SI technology SOURCE: Brown et al (2003) tions have been undertaken One of the main advantages of this process is that construction materials and corrosionresistance are more tractable at 500°C than at higher temperatures Another advantage is that, owing to its relatively low operating temperature, it can become compatible with several current and advanced nuclear reactor technologies clear]-SMR) reduces the CO2 emissions to the atmosphere by large quantities Elimination of the natural-gas-burning furnace in this process reduces the CH4 consumption by about 40 percent (Spath et al., 2000), which is parallel to the amount of CO2 emission reduction Cost of Nuclear Hydrogen Production Plants Steam Methane Reforming Steam methane reforming (SMR) is currently the main commercial technology for hydrogen production in the United States The SMR process requires high temperature, and the most common means of providing the heat for the process is through the burning of natural gas in the reforming furnaces, as described in the section “Hydrogen from Natural Gas,” earlier in this appendix The SMR process can be coupled to a high-temperature helium-cooled reactor, such as the MHR The MHR can function as the heat source operating at about 850°C, to replace the natural gas burning The high operating temperature can enable the process to take place at about 80 percent efficiency This approach (which might be called N [nu- The cost of hydrogen produced by electricity generated from existing nuclear power through water electrolysis is equivalent to using the electricity supplied by the grid for hydrogen production Today this cost is about a factor of higher than what is achievable by conventional SMR, with natural gas prices at $4.5/million Btu, even when the cost of hydrogen distribution is taken into account The improved power-cycle efficiencies of the advanced nuclear power plants may bring this cost differential in the future down to a factor of 1.5 The cost of hydrogen production using the MHR-SMR option is dependent on the cost of natural gas feedstock to the reforming process However, the cost from MHR-SMR is less sensitive to the cost of natural gas than is conventional Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 216 APPENDIX G SMR Hydrogen production cost estimates by EPRI (Sandell et al., 2003) and by the Massachusetts Institute of Technology (Yildiz and Kazim, 2003) indicate that this approach may be competitive with conventional SMR if the natural gas prices go above $6/million Btu However, their analyses did not include any taxes or fees for CO2 production The cost of hydrogen production by the nth-of-a-kind of MHR using the SI process was assessed by Brown et al (2003) The authors considered the cost of producing 800 t H2 per day using heat from four units of 600 MWth, each producing a coolant at 850ºC and having an overall efficiency of 42 percent Starting with an overnight cost of $470/ MWth for the nuclear electric plant, adding a heat exchanger, and replacing the electric generation capacity with a thermochemical plant, the total plant capital cost was found to be about $750/MWth (A recent review of the costs of nuclear power at recent plants—built in the past 10 years in Korea, Finland, and Japan—finds the overnight costs of plants to be in the range of $530 to $800/MWth [Deutch and Moniz, 2003].) The cost of running the MHR nuclear plant is estimated to be $93.9 million per year and the hydrogen plant to be $50.7 million per year This resulted in the cost of hydrogen production being about $1.50/kg However, it is possible to argue that future developments could facilitate reaching higher efficiency in the conversion of the nuclear thermal energy into hydrogen production Furthermore, larger numbers of units in one place could lead to lower costs; thus, larger plants could be associated with lower plant and operating costs Using optimistic assumptions about advances in nuclear plant construction and thermochemical plant efficiency, the cost of a 1200 t/day MHR-SI hydrogen plant may be assumed to reach a level of $600/MWth as the technology matures Including the usual contingency and permitting costs could add about one-third to this cost, thus leading to an effective plant cost estimate of $800/MWth and, assuming a 3-year construction time, the hydrogen production cost would be about $1.60/kg Advantages of Nuclear Energy Use for Hydrogen Production • Long-term domestic source Nuclear fuel will be available for a long time in the future, both domestically and worldwide Its price is not subject to global geopolitical pressures • Carbon implications If nuclear energy is used in the short term as the heat source in the SMR process, the result would be to reduce CO2 emissions by nearly 40 percent If one of the water-splitting processes is used, whether via a thermochemical process or an electrolysis approach, there will be no CO or CO2 emissions • Efficiency of the overall process In comparison with several other sources of hydrogen, the capability of attaining overall thermal-to-hydrogen energy efficiency in excess of 50 percent values by future technologies (e.g., the N-SMR, HTES, SI, and possibly other paths) is one of the advantages of nuclear energy use in hydrogen production The higher the temperatures that can be achieved for the reactors, the higher their efficiencies • Environmental implication There are no polluting emissions, or toxic gas, or particulate releases due to nuclear energy use for water splitting as the means for hydrogen production N-SMR will have CO2 emissions The watersplitting processes coupled to high-temperature reactors assume complete recycling of all reactants The volume of waste from the nuclear reactor cycle, while highly radioactive, is confined to small quantities compared with that from several other sources of energy, but it will have high levels of concentrated radioactivity Disadvantages of Nuclear Energy Use for Hydrogen Production • Efficiency of the conventional electrolysis process Even though it is a proven and clean technology, the low efficiency of low-temperature electrolysis makes the process uneconomic • Capital cost Both the new nuclear reactor plants and the hydrogen plants coupled to the nuclear plants are capitalintensive While the operating costs will be low owing to the expected high thermal efficiencies, the economics of the whole process may be disadvantageous Capital and lifecycle costs remain high, and plant designs are in need of simplification Enabling shorter periods of construction and increased factory-based manufacturing of components will also reduce the cost of the plants • Nuclear waste The nuclear waste disposal scheme remains to be finalized The Yucca Mountain project in Nevada has made good advances recently, and when licensed it can provide a destination for the spent fuel accumulating at the plant sites The development of a closed fuel cycle that involves the extraction and use of the fissile contents from the irradiated fuel would reduce the long-lived radioactivity associated with the waste to be sent to the repository • Proliferation Nuclear-fuel-cycle operations leave open the possibility of improper access to fissile material through theft or diversion Proliferation can be addressed through near-term measures designed to improve the proliferationresistance of current nuclear reactor operations and through long-term research to explore proliferation-resistant designs (PCAST, 1999) • Public concerns and permitting needs There is a public perception that nuclear energy and its emissions during normal operations increase radiation risks There is also some fear of widespread devastation in case of accidents These concerns would be reduced by the continued safe operation of existing plants and increased safety margins in new plants In addition, the recent concerns about terrorism may add to the public fear of nuclear plants The concerns of the public have led in the past to prolonged permitting periods for nuclear plants Thus, the permitting of commercial Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 217 APPENDIX G nuclear energy may pose a barrier to any expansion of this technology Research and Development Needs for Economic Hydrogen Production Using Nuclear Energy A high priority should be given to the development of high-temperature reactors that can provide coolants at temperatures higher than 800°C This objective seems most readily achievable using the helium-cooled gas reactor technology of HTGRs The ability of the reactor’s structural materials to operate for a long time at temperatures between 800°C and 1000°C needs to be established The R&D program should include the following: • Qualification of particle fuel materials to operate at the desired high temperatures, • Qualification of the irradiation properties of graphite and other structural materials at the desired range of temperatures, and • Operation and control of the helium power cycle at very high temperatures The efficiency of thermochemical schemes to accomplish water splitting without any CO2 emissions should be examined at a laboratory scale for the promising cycles, such as the SI cycles Materials compatibility issues and catalysts to enhance the reaction at lower temperatures should be pursued Reasonably-sized demonstration plants using the integrated process should be pursued in a few years for the most promising scheme Development of the high-temperature steam electrolysis process should be pursued The issues of materials durability, reduction of overvoltages, effects of the operating pressure, and separation of gas products in an efficient and safe manner should be investigated Development of a supercritical CO2 cycle should be given a high priority It can be directly used with a CO2cooled reactor such as the AGR, or indirectly used with the other reactors such as an HTGR It can be the bottoming cycle for a high-temperature reactor, whose coolant would supply heat at higher temperatures to a thermochemical plant Demonstration of the thermal conversion efficiency for a moderate-size turbine and compressor (in the MWe range) is needed to validate the cycle thermodynamics The safety issues of coupling the nuclear island to the hydrogen-producing chemical island need to be examined in order to establish the guidelines necessary for avoiding accident propagation from one island to the other Such guidelines would be needed even if the first application of nuclear hydrogen production was based on the nuclear-assisted SMR approach Comments on the Department of Energy Program The DOE nuclear hydrogen program is being pursued in two streams: one for reactor technology development and one for the chemical processes The DOE’s total program for reactor development was not reviewed by the committee, but it is understood that the DOE is pursuing the development of several versions of high-temperature reactors and is giving priority to the gas-cooled reactor options This priority is compatible with the reactors suitable for hydrogen production However, the molten salt-cooled graphite reactor may be a variant missing in the DOE program The DOE R&D program related to hydrogen from nuclear energy includes the chemical processes as well as the hightemperature electrolysis path A balanced approach is wise in order to benefit from high-efficiency electricity generation at lower temperatures than appear to be required for the thermochemical processes A systems analysis of the electrolysis approach is needed in order to determine the impact of the more efficient distributed generation capability The electrolyzer units can use materials similar to those of fuel cells that operate at high temperatures, and a synergistic materials program may be possible Finally, both electrolysis and thermochemistry are potentially applicable to the use of solar energy for hydrogen production The overall size of the hydrogen plant R&D appears modest at this point, seeking $2 million in new funds under the Hydrogen Fuel Initiative in FY 2004, in addition to the $2 million being spent through the Nuclear Energy Research Initiative That level might be appropriate for laboratorylevel investigations of one option Covering several options in both the thermochemistry and high-temperature electrolysis properly requires a level of $10 million to $20 million per year for or years before reaching a conclusion on the best approach for a large (100 MWth) demonstration plant based on the most promising option The current R&D portfolio does not allow for “out of the box” thinking It needs to encourage exploratory basic research involving other approaches, such as methods of enhancing hydrogen production by radiolysis or photolysis in properly designed radiation sources Summary Hydrogen can be produced from current nuclear reactors using electrolysis of water More efficient hydrogen production may be attained by thermochemical splitting of water or electrolysis of high-temperature steam Another possibility is the use of nuclear energy as the source of heat for steam methane reforming (SMR) The water-splitting approach releases no CO2 Efficient water-splitting processes and nuclear-SMR all require temperatures well above 700°C Current water-cooled reactors produce temperatures under 350°C, and cannot be used for efficient hydrogen production Advanced reactors, such as gas-cooled reactors, involve coolants that can achieve the required high temperatures As indicated, the DOE’s total program for reactor development was not reviewed by the committee, but it is understood to include high-temperature reactors, with focus on Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 218 APPENDIX G gas-cooled reactor options This priority is compatible with the reactors suitable for hydrogen production The DOE R&D program on the chemical processes for nuclear hydrogen production appears to favor thermochemical processing over the high-temperature electrolysis path A more balanced approach would be wiser in order to make use of potentially high efficiency electricity generation at lower temperatures than are required for thermochemical processes Furthermore, the electrolyzer units can use materials similar to those for fuel cells that operate at high temperatures, and a synergistic materials program may be possible The research budget for the hydrogen technology part of the Department of Energy’s nuclear hydrogen program is at the level of $4 million for FY 2004, which appears to be modest The examination of several options for promising cycles, including the process kinetics, the material’s ability to withstand the aggressive chemistry and temperatures, the separation of fluids, and the overall efficiency of the systems involved, requires a significantly higher level of funding for a few years, until the most promising process is selected for demonstration Advances made in the thermochemical cycles or in high-temperature electrolysis are of benefit to hydrogen production using other fuel sources, such as solar energy A portfolio of advancing near-term technologies needs to be maintained while innovative approaches are being examined The research portfolio should also include safety aspects of integrating the nuclear reactor with the chemical plant for hydrogen production This aspect of the program is an important ingredient in establishing guidelines for the designs to avoid the potential for accident propagation The involvement of industry in assessing the practicality and cost of the technology that might be selected for development in order to ensure the highest economic potential should be emphasized HYDROGEN FROM ELECTROLYSIS Two basic options exist for producing hydrogen One way is to separate the hydrogen from hydrocarbons through processes referred to as reforming or fuel processing The second way to make hydrogen is from water, using the process of electrolysis to dissociate water into its separate hydrogen and oxygen constituents Electrolysis technologies that have been in use for decades both dissociate water and capture oxygen and/or hydrogen, primarily to meet industrial chemical needs Electrolysis has also played a critical role in life support (oxygen replenishment) in space and submarine applications over the past several decades Importance of Electrolysis Making hydrogen through electrolysis generally consumes considerably more energy per unit of hydrogen produced than does making hydrogen from hydrocarbons Nonetheless, electrolysis is of interest as a potential source of hydrogen energy for several reasons First, water (and the hydrogen it contains) is more abundant than hydrocarbons are Depletion and geopolitical concerns for water are in general far less serious than are those for hydrocarbons Further, there are geographical regions in the nation and around the world where hydrocarbons (especially natural gas, the predominant source of hydrogen reformation) are simply not available; hydrogen from water may be the only practical means of providing hydrogen in such settings Second, the net energy costs of making hydrogen through electrolysis must be viewed in an economic context Electrolysis can be a means of converting low-cost Btus (e.g., coal) into much-higher-value Btus if the result is to replace gasoline or other transport fuels Third (and as is discussed further in the analysis that follows), electrolysis is seen as a potentially cost-effective means of producing hydrogen on a distributed scale and at costs appropriate to meet the challenges of supplying the hydrogen needs of the early generations of fuel cell vehicles Electrolyzers are compact and can realistically be situated at existing fueling stations Fourth, electrolysis presents a path to hydrogen production from renewably generated electrical power From an energy perspective, electrolysis is literally a way to transform electricity into fuel Electrolysis is thus the means of linking renewably generated power to transport fuels markets Currently, renewable solar, wind, and hydro power, by themselves, produce only electricity And finally, electrolyzers operating in tandem with power-generating devices (including fuel cells) present a new architecture for markets related to distributed energy storage Various electrolyzer makers are developing products that can make hydrogen when primary electricity is available, and then store and use that hydrogen for subsequent regeneration into electricity as needed For example, several firms are involved with developing backup power devices that operate in the to 20 kilowatt (kW) range for up to 24 hours, well beyond the capability of conventional batteries This same concept is being applied directly to renewable sources, creating the means to produce power-ondemand from inherently intermittent renewables And finally, electrolysis may play a role in regenerative braking on vehicles Electrolyzers and hydrogen have the appropriate scale and functionality to become part of the distributed generation marketplace as the cost of electrolyzers comes down over time Technology Options Current electrolysis technologies fall into two basic categories: (1) solid polymer (which provides for a solid electrolyte) and (2) liquid electrolyte, most commonly potassium hydroxide (KOH) In both technologies, water is introduced into the reaction environment and subjected to an electrical current that causes dissociation; the resulting hydrogen and oxygen atoms are then put through an ionic transfer mecha- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 219 APPENDIX G nism that causes the hydrogen and oxygen to accumulate in separate physical streams Solid polymer, or proton exchange, membranes were developed at General Electric and other companies in the 1950s and 1960s to support the U.S space program A proton exchange membrane (PEM) electrolyzer is literally a PEM fuel cell operating in reverse mode When water is introduced to the PEM electrolyzer cell, hydrogen ions are drawn into and through the membrane, where they recombine with electrons to form hydrogen atoms Oxygen gas remains behind in the water As this water is recirculated, oxygen accumulates in a separation tank and can then be removed from the system Hydrogen gas is separately channeled from the cell stack and captured Liquid electrolyte systems typically utilize a caustic solution to perform the functions analogous to those of a PEM electrolyzer In such systems, oxygen ions migrate through the electrolytic material, leaving hydrogen gas dissolved in the water stream This hydrogen is readily extracted from the water when directed into a separating chamber KOH systems have historically been used in larger-scale applications than PEM systems Electrolyzer Corporation of Canada (now Stuart Energy) and the electrolyzer division of Norsk Hydro have built relatively large plants (100 kg/hour and larger) to meet fertilizer production needs in locations around the globe where natural gas is not available to provide hydrogen for the process The all-inclusive costs of hydrogen from PEM and KOH systems today are roughly comparable Reaction efficiency tends to be higher for KOH systems because the ionic resistance of the liquid electrolyte is lower than the resistance of current PEM membranes But the reaction efficiency advantage of KOH systems over PEM systems is offset by higher purification and compression requirements, especially at small scale (1 to kg/hour) Today’s Electrolysis Markets Chemical and Niche Energy Applications Electrolyzers are today commercially viable only in selected industrial gas applications (excepting various noncommercial military and aerospace applications) Commercial applications include the previously mentioned remote fertilizer market in which natural gas feedstock is not available The other major commercial market for electrolysis today is the distributed, or “merchant,” industrial hydrogen market This merchant market involves hydrogen delivered by truck in various containers Large containers are referred to as tube trailers An industrial gas company will deliver a full tube trailer to a customer and take the empty trailer back for refilling Customers with smallerscale requirements are served by cylinders that are delivered by truck and literally installed by hand In general, the smaller the quantities of hydrogen required by a customer, the higher will be the all-inclusive delivered cost Tube trailer customers (e.g., semiconductor, glass, or specialty metals manufacturers) pay in the range of $3.00/ 100 scf, or about $12/kg Cylinder customers (e.g., laboratories, research facilities, and smaller manufacturing concerns) pay at least twice the tube trailer price The value of hydrogen in distributed chemical markets today is much higher than the value of hydrogen if it were to be used as fuel The price of hydrogen will need to be in the $2.00/kg range to compete with conventional fuels for transportation It will take significant cost-reduction and efficiency improvements for electrolytic hydrogen to compete in vehicle fueling markets Nonetheless, a number of stationary energyrelated applications for electrolytic hydrogen are beginning to materialize These smaller but higher-value energy applications merit the DOE’s attention and support as a means of advancing the practical development of hydrogen from electrolysis for future, larger-scale fueling markets Off-Grid Renewables Applications Power-on-demand from inherently intermittent renewables is another interesting application for electrolysis Offgrid, renewable-based systems need electricity at night or when the wind doesn’t blow The value difference between electricity when available and when needed is often great enough to merit the utilization of batteries to fill this gap In circumstances in which the amount and duration of stored energy becomes relatively large in relation to battery functionality, an electrolyzer-hydrogen regenerative system may prove a lower-cost solution, ultimately enabling greater use of renewables for meeting off-grid energy needs Current Electrolyzer Technology and Fueling Costs The cost of hydrogen from electrolysis is dominated by two factors: (1) the cost of electricity and (2) capital-cost recovery for the system A third cost factor—operation and maintenance expenses (O&M)—adds perhaps to percent to total annual costs The electrochemical efficiency of the unit, coupled with the price of electricity, determine the variable cost The total capital cost of the electrolyzer unit, including compression, storage, and dispensing equipment, is the basis of fixed-cost recovery Electrochemical Efficiency Proton exchange membranes, whether operating in electrolysis mode or fuel cell mode, have the property of higher efficiency at lower current density There is a 1:1 relationship in electrolysis between the rate of hydrogen production and current applied to the system The energy required in the theoretical efficiency limit of any water electrolysis process is 39.4 kWh per kilogram PEM electrolyzers operating at low current density can approach this efficiency limit However, the quantities of hy- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 220 APPENDIX G drogen produced at low current density are small, resulting in very high capital costs per unit of hydrogen produced As shown in Figure G-9, cell stack efficiencies drop to 75 percent when current densities rise into the range of 1000 amps per square foot (ASF) As previously stated, the electrochemical efficiency of KOH systems is higher over a broader range of current densities, but this higher reaction efficiency is offset at least in part by higher compression and purification costs, as well as by higher costs associated with managing the liquid electrolyte itself The committee believes that current technology is capable of producing an electrolyzer-based fueling facility having the capacity to produce 480 kg/day, or 20 kg/hour This plant would be capable of fueling 120 cars per day, assuming an average purchase of kg per car A plant of this scale would of necessity today be a KOH system, but with additional development, PEM technology should be capable of providing systems of comparable scale Electrolyzer systems of this scale should be capable of operating with an overall efficiency of 63.5 percent lower heating value [LHV], including all parasitic loads other than compression The electrolyzer is assumed to be able to generate hydrogen at an internal pressure in the 150 psi range; supplementary compression will be required to raise the pressure to automotive fueling pressures in the 7000 psi (400 atm) range The electrical requirement associated with compression is assumed at 2.3 kW/kg/hour, adding about percent to the plant’s electrical consumption and bringing overall efficiency down to about 59 percent Equipment Costs Regarding capital cost recovery, the cost of the 480 kg/ day system, excluding compression and dispensing, is assumed at $1000/kW input The cost of the complete fueling system is summarized in Table G-5 The total cost of a system at this scale would be about $2.5 million It is anticipated that electrolysis technology scales with an 85 percent factor, so smaller-scale systems, with somewhat higher unit costs, are entirely feasible For example, a facility with half the fueling capability (60 cars per day) would cost about $1.25 million, plus a 15 percent scaling factor The scalability of electrolysis is one of the important factors relating to its likely use in early-stage fuel cell vehicle adoption The electrochemical efficiency of electrolysis is essentially independent of scale 90 Kilowatt-hours consumed by cell stack per kg H2 produced 80 70 60 50 40 Base case Advanced case 30 75% efficiency line 20 500 1000 1500 2000 Cell stack current density (amperes per square foot) FIGURE G-9 Electrolysis cell stack energy consumption as a function of cell stack current density Copyright © National Academy of Sciences All rights reserved 2500 3000 The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 221 APPENDIX G TABLE G-5 Capital Costs of Current Electrolysis Fueler Producing 480 Kilograms of Hydrogen per Day Unit Cost ($) Total Cost ($ millions) Electrolyzer unit Hydrogen compressor Hydrogen storage Hydrogen dispenser Total process units 1,000/kW 3,000/kW 100/gal 15,000/unit 1.17 0.16 0.24 0.02 1.59 General facilities Engineering, permitting, start-up Contingencies Working capital and miscellaneous Total capital 20% 10% 10% 5% 0.32 0.16 0.16 0.08 2.31 Siting factor (110% of Gulf Coast) Total TABLE G-6 All-Inclusive Cost of Hydrogen from Current Electrolysis Fueling Technology 0.23 2.54 NOTE: See Table E-37 in Appendix E in this report All-Inclusive Cost of Hydrogen Fuel from Electrolysis The total cost of electrolytic hydrogen from currently available technology is summarized in Table G-6 This table assumes a 14 percent capital cost-recovery factor, and presents the total cost (variable, capital, and O&M) associated with the assumed fueling facility The delivered cost of grid electricity is assumed at cents/kWh Total costs are in the range of $6.50/kg Future Electrolysis Technology Enhancements Among the research priorities that can improve the efficiency and/or reduce the cost of future electrolysis fueling devices are the following: Efficiency-Enhancing Objectives Reducing the ionic resistance of the membrane New membranes will be thinner and will incorporate improved ion-conducting formulations that lower the resistance of the membrane and cause more of the electrical energy delivered to the membrane to be translated into hydrogen chemical energy and less into heat In alkaline (KOH) systems, ionic resistance tends to be less than in proton exchange membrane systems, but KOH systems tend to have more complex materials handling and pressurization regimes Reducing other (parasitic) system energy losses A variety of parasitic loads, such as power conditioning, can be reduced through system redesign and optimization Power conditioning is one area of efficiency loss; current systems lose as much as 10 percent electrical efficiency with currently available inverters These losses will be reduced by half or more with new inverters redesigned to meet the specific needs of electrolyzers Power supply companies will Cost per Year per Station Cost per ($ million) Kilogram ($) Nonfuel variable operation and maintenance (1% of capital) Electricity (7 cents/kWh) Variable operating costs Fixed operating costs (2%/year of capital) Capital charges (14%/year of capital) Total cost 0.025 0.16 0.605 0.630 0.051 3.84 4.00 0.32 0.354 1.035 2.24 6.56 need to see enough market assurance before those redesigns will be forthcoming Other cost reductions can come from optimizing an array of components and the overall operating system Volume manufacturing and pricing are also important cost factors In calling out the efficiency costs of alternating current/direct current (ac/dc) power conversion, one advantage of renewable power becomes worthy of note Renewables generate dc power that can be applied to the dc-using electrolyzer cell stack without inversion This incremental efficiency advantage associated with renewables may become material as the cost of power from renewables continues to drop Reducing current density Conversion efficiencies are a function of electric current density, so the substitution of more electrolyte or more cell surface area has the impact of reducing overall power requirements per unit of hydrogen produced Improved catalyst deposition technology will also lower the amount and cost of materials per unit of hydrogen production Operating system redesign for optimization is another area of cost reduction opportunity Technology advances will be required to get to efficiencies beyond the current level One area that promises to improve efficiency is higher temperature, which has the effect of lowering the ionic resistance within the cell environment Higher temperatures PEM technologies typically operate at low temperatures (below 100°C) because of membrane durability limitations Higher-temperature proton exchange membranes are in development; these should be able to tolerate significantly higher temperatures and thereby deliver higher efficiencies Cost Reduction Objectives The committee believes that PEM electrolysis is subject to the same basic cost reduction drivers as those for fuel cells Cost breakthroughs in (1) catalyst formulation and loading, (2) bipolar plate/flow field, (3) membrane expense and durability, (4) volume manufacturing of subsystems and modules by third parties, (5) overall design simplifications, and (6) scale economies (within limits) all promise to lower Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 222 APPENDIX G the cost per unit of production The committee finds it plausible that electrolyzer capital costs can fall by a factor of 8— from $1000 per kW in the near term to $125 per kW over the next 15 to 20 years, contingent on similar cost reductions occurring in fuel cells This reduction seems attainable when considered against the claims by fuel cell developers that they can bring the cost of fuel cells to $50/kW from today’s nearly $5000/kW prices Advanced Future Electrolysis Technologies The committee was presented with the view that technologies beyond PEM may offer higher overall efficiency by going to significantly higher temperatures and design concepts Solid oxide fuel cell technology operates at much higher temperatures than PEM technology does, and so it may be a source of advanced electrolyzer performance going forward Efficiencies moving toward 95 percent may be possible with solid oxide But solid oxide systems operating at 500°C to 1000°C are probably at least and perhaps 10 years in the future Solid oxide systems, because of their thermal management needs, may be confined to systems of significantly larger scale than PEM systems Solid oxide electrolyzers may be scalable down to gas station duty, but that remains to be proven Clearly, PEM systems can scale appropriately for distributed refueling duty Electrolysis/Oxidation Hybrids Still further advances in electrolysis technology, such as have been conceived at Lawrence Livermore National Laboratory, involve solid oxide electrolyzer/hydrocarbon hybrids The hybrid concept involves enhancing the efficiency of the already-hightemperature electrolysis process by using the oxidation of natural gas as a means of intensifying the migration of oxygen ions through the electrolyte and thereby reducing the effective amount of electric energy required to transport the oxygen ion The concept appears to offer the potential for significantly improved net electrochemical efficiency However, the concept relies on a number of technical breakthroughs in harnessing solid oxide technology and ultimately requires a separate stream of methane or another combustible fuel supply in addition to water and electricity Future Electrolytic Hydrogen Fuel Costs The committee’s assessment of electrolysis improvements focused on PEM-based technologies rather than on advanced concepts The effect is to offer a view of futures that are based on today’s technology and not rely on new technological breakthroughs that, should they occur, would only enhance the cost and performance picture Overall, improvements in electrolyzer performance will come from three advancements: (1) improved electrochemical efficiency—efficiency gains from 63.5 percent system efficiency to 75 percent system efficiency (LHV) could be attainable; (2) system costs—as stated above, the system capital costs may be reduced by a factor of 8, from $1000/ kW to $125/kW, driven largely by the same cost factors that must be addressed by fuel cell developers if there is to be any meaningful penetration by fuel cells into the transportation marketplace; and (3) compressor performance and cost are seen to be improving as a result of a variety of emerging hydrogen energy alternatives, all of which depend on taking hydrogen to significantly higher energy densities than can today be attained with only hydrogen compression The resulting impact of technology development on the future cost of hydrogen from electrolysis is summarized in Table G-7 Variable costs (electricity) fall as a result of improved electrochemical efficiency The biggest change comes from the large drop in capital costs, which translates directly into lower capital cost per unit of production This, along with lower compression costs, results in reduced allinclusive costs of hydrogen from $6.58/kg using current technology to $3.94/kg as a result of future improvements Sensitivity to Electricity Costs Figure G-10 illustrates the considerable sensitivity of the cost of hydrogen from electrolysis to the price of input electricity Each cent reduction in the price of electricity reduces the cost of electrolytic hydrogen fuel by 53 cents/kg, or more than percent per penny Effective utilization of electrolysis as a fueling option will involve the cooperation of utilities and rate-making bodies Environmental Impacts of Electrolysis The environmental impact of the use of electrolysis to produce hydrogen depends on the source of electricity The TABLE G-7 Cost of Hydrogen from Future Electrolysis Fueling Technology Capital Cost Unit Cost ($) Cost per Station ($ million) Electrolyzer 125/kW Compressor 1,500/kW Storage 75/gal Dispenser 10,000/unit Other Total capital (with a 1.1 siting factor) 0.13 0.03 0.19 0.01 0.17 0.57 Cost $/kg Nonfuel variable cost Electricity Fixed operating costs Capital charges Total 0.04 3.31 0.07 0.51 3.93 NOTE: See Table E-38 in Appendix E in this report Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 223 APPENDIX G Carbon tax Capital charges Fixed costs, %/yr of capital Nonfuel O&M, %/yr of capital Electricity Cost per kg of hydrogen ($) 0.01 0.02 0.03 0.04 0.05 0.06 0.08 0.10 0.12 Electricity price (dollars per kilowatt-hour) FIGURE G-10 Sensitivity of the cost of hydrogen from distributed electrolysis to the price of input electricity electrolysis process produces little if any CO2 or other greenhouse gas emissions per se Electrolyzers contain no combustion devices, and the only input to the process other than electricity is pure water However, there does exist a relationship between emissions and electrolysis Any pollution associated with electricity consumed by the electrolyzer needs to be taken into account As stated previously, one fundamental appeal of electrolysis is that it creates a path for converting renewable power into fuel But the low capacity factors of renewables (other than geothermal and hydro power) make an allrenewables case very difficult on an economic basis Electricity from nuclear plants is also non-emitting on a greenhouse gas emissions basis, but the outlook for additional nuclear plants is uncertain at best Power from the grid is assumed to derive from the grid’s average generating mix With today’s grid mix, about 17.6 kg CO2 are emitted per kilogram of hydrogen As the portfolio of energy resources utilized to supply electric power evolves, the amount of CO2 emitted to produce kg H2 could either increase or decrease Electrolysis as an Early-Stage Transitional Hydrogen Fuel Source Electrolysis may be particularly well suited to meeting the early-stage fueling needs of a fuel cell vehicle market Electrolyzers scale down reasonably well; the efficiency of the electrolysis reaction is independent of the size of the cell or cell stacks involved And the balance of plant costs in an electrolyzer are also fairly scalable The compact size of electrolyzers makes them suitable to be placed at or near existing fueling stations And finally, electrolyzers can utilize existing water and electricity infrastructures to a considerable extent, obviating the need for a new pipeline or surface hydrogen transport infrastructure that would be required of larger, central station hydrogen production technologies Summary Electrolytic hydrogen production is an existing technology that serves a high-value industrial chemicals-based mar- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 224 APPENDIX G ket today The key to adapting this technology to meet energy-related applications in the future is cost reduction and performance enhancement The Department of Energy has already identified several technology objectives relating to electrolytic hydrogen production Hydrogen can be made from renewable sources, enabling a perfectly sustainable energy path The falling cost of renewable energy resources and the improving cost and efficiency outlook for electrolysis contribute to the prospect that renewably sourced electrolytic hydrogen may be competitive with other hydrogen supply in at least some instances Electrolyzers typically operate from grid-quality power, so a new variety of power control and conditioning equipment needs to be developed in order for electrolyzers to operate efficiently from renewable sources The prospect exists for good efficiency in converting renewable power to hydrogen, insofar as electrolyzers require direct current and renewables generate direct current, so there are no losses associated with ac/dc conversion HYDROGEN PRODUCED FROM WIND ENERGY Introduction The production of hydrogen from renewable energy sources is often stated as the long-term goal of a mature hydrogen economy (Turner, 1999) As such the development of cost-effective renewable technologies should clearly be a priority in the hydrogen program, especially since considerable progress is required before these technologies reach the levels of productivity and economic viability needed to compete effectively with the traditional alternatives Thus, basic renewables research needs to be expanded and the development of renewable hydrogen production systems accelerated Of all the renewables currently on the drawing boards, in the near to medium term, wind arguably has the highest potential as an excellent source for producing pollution-free hydrogen, using the electricity generated by the wind turbines to electrolyze water into hydrogen and oxygen The issues for its successful development and deployment are threefold: (1) further reducing the cost of wind turbine technology and the cost of the electricity generated by wind, (2) reducing the cost of electrolyzers, and (3) optimizing the wind turbine-electrolyzer with hydrogen storage system This section discusses current costs and projections for future costs of electricity produced by wind energy and then looks at the cost of producing hydrogen using an integrated wind turbine-electrolyzer system (Discussion of electrolyzer technology is presented in the section “Hydrogen from Electrolysis.”) This section focuses on wind energy systems that would be deployed on a distributed scale Status of Wind Energy in the World Today While wind energy has been one of humanity’s primary energy sources for transporting goods, milling grain, and pumping water for several millennia, its use as an energy source began to decline as industrialization took place in Europe and then in America The decline was at first gradual as the use of petroleum and coal, both cheaper and more reliable energy sources, became widespread, and then it fell more sharply as power transmission lines were extended into most rural areas of industrialized countries The oil crises of the 1970s, however, triggered renewed interest in wind energy technology for grid-connected electricity production, water pumping, and power supply in remote areas, promoting the industry’s rebirth By 2002, grid-connected wind power in operation surpassed 31,000 MW worldwide (see Figure G-11) In the early 1980s, the United States accounted for 95 percent of the world’s installed wind energy capacity (see Figure G-11) The U.S share has since dropped to 15 percent in 2002 Other countries dramatically increased their capacity starting in the mid-1990s, while the U.S capacity essentially stagnated until 1999, when more than 600 MW in new capacity were installed in a rush to beat an expiring production tax credit for utility-scale projects This credit has since been extended through December 31, 2003 In 2001 and 2002, the total installed wind capacity doubled in the United States, and in 2003 it was expected to increase another 25 percent, to more than 6000 MW, with installations of 1400 to 1600 MW of new wind power (AWEA, 2003) The decline in the U.S capacity world share can be explained by a combination of economic factors and changes in government-sponsored support programs that impeded the development of new capacity The U.S wind industry was born in 1981 in the aftermath of the world oil crises of 1973–1974 and 1978–1979 Wind energy was not costcompetitive with fossil fuel energy, but federal legislation guaranteed a market for wind-generated power and offered generous tax credits to developers of wind energy However, 1986 marked the beginning of the slowdown in U.S wind energy development The availability of relatively cheap oil and natural gas and improvements in gas generating technology, coupled with the expiration of federal tax credits at the end of 1985, meant that wind energy remained significantly more costly than fossil fuels The tax credit incentives had been more effective in building capacity than in maintaining productivity, and as a consequence electricity generation from wind did not grow as rapidly as initially anticipated This trend appears to have reversed itself in the past years, with more than a 22 percent annual increase in installed generating capacity since 1998, despite the recent problems permeating the electric utility industry This recent growth, coupled with progressive state policies—30 states have installed wind capacity—the continuing extension of the federal wind energy production tax credit, and maturing wind turbine technology, appears to have signaled a rebirth for the industry in the United States Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 225 APPENDIX G 35,000 30,000 World United States Megawatts 25,000 20,000 15,000 10,000 5,000 1981 1983 1985 1987 1989 1991 1993 1995 1997 1999 2001 Year FIGURE G-11 WEA (2000) Wind generating capacity, 1981–2002, world and U.S totals SOURCES: AWEA (2003), Worldwatch Institute (1999), and Potential for Wind Energy: Technical and Resource Availability The main technical parameter determining the economic success of a wind turbine system is its annual energy output, which in turn is determined by parameters such as average wind speed, statistical wind speed distribution, distribution of occurring wind directions, turbulence intensities, and roughness of the surrounding terrain Of these, the most important and sensitive parameter is the wind speed, which increases exponentially with height above the ground; the power in the wind is proportional to the third power of the momentary wind speed As accurate meteorological measurements and wind energy maps (as shown in Figure G-12) become more commonly available, wind project developers can more reliably assess the long-term economic performance of wind farms Estimates show that U.S wind resources could provide more than 10 trillion kWh (Deyette et al., 2003; Elliott and Schwartz, 1993), which includes land areas with wind class or above (corresponds to wind speeds greater than meters per second [m/s] [15.7 mph] at a height of 50 m), within 20 miles of existing transmission lines, and excludes all urban and environmentally sensitive areas This is over times the total electricity currently generated in the United States In the DOE’s Hydrogen Posture Plan (DOE, 2003a), wind availability is estimated to be 3250 GW, equivalent to the above value for a capacity factor of 35 percent In 2002, installed wind capacity was about GW generating 12.16 billion kWh, corresponding to a capacity factor of 29 percent (EIA, 2003) There has been a gradual growth of the unit size of commercial machines since the mid-1970s In the mid-1970s the typical size of a wind turbine was 30 kW By 1998, the largest units installed had a capacity of 1.65 MW, while turbines with an installed power of MW have now been introduced into the market with over MW machines being developed The trend toward larger machines is driven by the demand side of the market to utilize economies of scale and to reduce visual impact on the landscape per unit of installed power, and by the expectation that the offshore potential will be growing Recent technical advances have made wind turbines more controllable and grid-compatible and have reduced the number of components, making them more reliable and robust The technology is likely to continue to improve Such im- Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 226 FIGURE G-12 APPENDIX G Hydrogen from wind power availability SOURCE: U.S Department of Energy, National Renewable Energy Laboratory provements include enhanced performance at variable wind speeds, thereby capturing the maximum amount of wind according to local wind conditions, and better grid-compatibility These advancements can occur through better turbine design and optimization of rotor blades, more efficient power electronic controls and drive trains, and better materials Furthermore, economies of scale and automated production may also continue to reduce costs (Corey et al., 1999) Economics of Wind Energy Larger turbines, more efficient manufacturing, and careful siting of wind machines have brought the installed capital cost of wind turbines down from more than $2500/kW in the early 1980s to less then $1000/kW today at the best wind sites However, on-stream capacity factor for wind is generally in the range of 30 to 40 percent, which raises the effective cost While this decrease is due primarily to improvements in wind turbine technology, it is also a result of the general increase in wind farm size, which benefits from economies of scale, as fixed costs can be spread over a larger generating capacity As a result, wind energy is currently one of the most cost-competitive renewable energy technologies, and in some places it is beginning to compete with new fossil fuel generation (Reeves, 2003) Worldwide, the cost of generating electricity from wind has fallen by more than 80 percent, from about 38 cents/ kWh in the early 1980s to a current range for good wind sites located across the United States of to cents/kWh,19 with average capacity factors of close to 30 percent The current federal production tax credit of 1.8 cents/kWh for windgenerated electricity lowers this cost to below cents/kWh at the best wind sites This is an order-of-magnitude decrease in cost in two decades Analysts generally forecast that costs will continue to drop significantly as the technology improves further and the market grows around the world (Corey et al., 1999), though some not (for example, the EIA) In the committee’s analysis, for possible future technologies it is assumed that the cost of electricity generated using wind turbines decreases to cents/kWh (including transmission costs) This assumption is based on a wind tur19Cost of electricity (COE) estimates from the National Renewable Energy Laboratory (NREL), Lawrence Berkeley National Laboratory (LBNL), Northern Power, and GE regarding the current cost of wind-generated electricity excluding the federal production tax credit (PTC) subsidy of 1.8 cents/ kWh NREL: Personal communication with Lee Fingersh: 3.2 to cents/ kWh today, depending on location; August 2003 See the web site http:// www.eere.energy.gov/wind/web.html Accessed December 10, 2003 LBNL: Personal communication with Ryan Wiser: Wind prices are about 4.3 to 5.3 cents/kWh throughout the Midwest, 5.8 cents/kWh in the MidAtlantic, around 5.8 to 6.8 cents/kWh in California, and perhaps 4.3 to 5.8 cents in the Northwest; August 2003 Northern Power: to cents/kWh for wind farms greater than 50 MW located at good wind sites, while for one or two turbines located at a marginal wind site, prices can be as high as to 12 cents/kWh or higher Dan Reicher, Northern Power Systems, “Hydrogen: Opportunities and Challenges,” presentation to the committee, June 2003 Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs http://www.nap.edu/catalog/10922.html 227 APPENDIX G bine capital cost of $500/kW, total capital costs of $745/kW, and a capacity factor of 40 percent.20 The expectation is that wind turbine design will be refined and economies of scale will accrue While these values can be considered optimistic (e.g., by the EIA), others predict even lower values, given successful technology advancement and supportive policy conditions (Bailie et al., 2003; Corey et al., 1999; WEA, 2000) In the future, cost reduction can occur with multiple advancements: further improvements in turbine design and optimization of rotor blades, more-efficient power controls and drive trains, and improvements in materials The improvements in materials are expected to facilitate increased turbine height, leading to better access to the higher-energy wind resources available at these greater heights The desire of new U.S vendors to participate in wind energy markets will increase competition, leading to an overall optimization and lower cost of the wind turbine system Wind technology does not have fuel requirements as coal, gas, and petroleum generating technologies However, both the equipment costs and the costs of accommodating special characteristics such as intermittence, resource variability, competing demands for land use, and transmission and distribution availability can add substantially to the costs of generating electricity from wind For wind resources to be useful for electricity generation and/or hydrogen production, the site must (1) have sufficiently powerful winds, (2) be located near existing distribution networks, and (3) be economically competitive with respect to alternative energy sources While the technical potential of wind power to fulfill the need for energy services is substantial, the economic potential of wind energy will remain dependent on the cost of wind turbine systems as well as the economics of alternative options Hydrogen Production by Electrolysis from Wind Power Hydrogen production from wind power and electrolysis is a particularly interesting proposition since, as just discussed, among renewable sources, wind power is economically the most competitive, with electricity prices at to cents/kWh at the best wind sites (without subsidies) This means that wind power can generate hydrogen at lower costs than those for any of the other renewable options available today In the committee’s analysis, it considered wind deployed on a distributed scale, thus bypassing the extra costs and requirements of hydrogen distribution Since hydrogen from wind energy can be produced close to where it will be used, there is a clear role for it to play in the early years of hydrogen infrastructure development, especially as the committee 20This is an average value Sites in the Great Plains, for example, could have higher capacity factors The committee decided against using ranges for technology performance parameters in its analysis believes that a hydrogen economy is most likely, at least initially, to develop in a distributed manner For distributed wind-electrolysis-hydrogen generation systems, it is estimated that by using today’s technologies hydrogen can be produced at good wind sites (class and above) without a production tax credit for approximately $6.64/kg H2, using grid electricity as backup for when the wind is not blowing The committee’s analysis considers a system that uses the grid as backup to alleviate the capital underutilization of the electrolyzer with a wind capacity factor of 30 percent It assumes an average cost of electricity generated by wind of cents/kWh (including transmission costs), while the cost of grid electricity is pegged at cents/kWh, a typical commercial rate This hybrid hydrogen production system has pros and cons It reduces the cost of producing the hydrogen, which without grid backup would otherwise be $10.69/kg H2, but it also incurs CO2 emissions from what would otherwise be an emission-free hydrogen production system The CO2 emissions are a product of using grid electricity; they are 3.35 kg C per kilogram of hydrogen In the future the wind-electrolysis-hydrogen system could be substantially optimized The wind turbine technology could improve, reducing the cost of electricity to cents/kWh with an increased capacity factor of 40 percent, as discussed previously, and the electrolyzer could also come down substantially in cost and could increase in efficiency (see the discussion in the section “Hydrogen from Electrolysis”) The combination of the increase in capacity factor and the reduction in the capital cost of the electrolyzer and cost of wind-generated electricity results in eliminating the need for using grid electricity (price still pegged at cents/kWh) as a backup The wind machines and the electrolyzer are assumed to be made large enough that sufficient hydrogen can be generated during the 40 percent of the time that the wind turbines are assumed to provide electricity Due to the assumed reductions in the cost of the electrolyzer and the cost of windturbine-generated electricity, this option is now less costly than using a smaller electrolyzer and purchasing grid-supplied electricity when the wind turbine is not generating electricity Hydrogen produced in this manner from wind with no grid backup is estimated to cost $2.85/kg H2, while for the alternative system with grid backup it is $3.38/kg H2 Furthermore, there is now the added advantage of a hydrogen production system that is CO2-emission free The results of the committee’s analysis are summarized in Table G-8 Wind-electrolysis-hydrogen production systems are currently far from optimized For example, the design of wind turbines has to date been geared toward electricity production, not hydrogen To optimize for better hydrogen production, integrated power control systems between the wind turbine and electrolyzer need to be analyzed, as should hydrogen storage tailored to the wind turbine design Furthermore, there is the potential to design a system that can coproduce electricity and hydrogen from wind Under the right circumstances this could be more cost-effective and Copyright © National Academy of Sciences All rights reserved ... achieving the vision of the hydrogen economy; the path will not be simple or straightforward Many of the committee’s observations generalize across the entire hydrogen economy: the hydrogen system... stimulated the interest of both the technical community and the broader public in the ? ?hydrogen economy. ” As it is frequently envisioned, the hydrogen economy comprises the production of molecular hydrogen. .. from the accustomed benefits of the current infrastructure? The future of the hydrogen economy depends on the answer Copyright © National Academy of Sciences All rights reserved The Hydrogen Economy:

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